Entering edit mode
David O'Brien
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10
@david-obrien-5970
Last seen 10.3 years ago
I'm trying to analyze an RNA-seq experiment where the PCA plot shows
better
clustering by the day the experiment was done rather than treatment
type.
Using edgeR to determine differentially expressed genes resulted in
less
than 5 genes with an FDR under 5%. Creating a GLM model to remove
batch
effects for day of experiment as stated in the edgeR manual resulted
in 42
genes with an FDR less than 5%. An improvement, but still not good. So
I
tried using ComBat and the result was 986 genes with an FDR under 5%.
Looking at the GO enrichment, the differentially expressed genes seem
to
make sense, but since ComBat was developed for microarrays, I'm
concerned
that there may be some caveats with this approach that I'm missing.
Looking
at the top genes below, the log2 fold change is really low and
generally
this just seems too good to be true. So my question is: Are there any
reasons why using ComBat with RNA-seq data is not legit? And if so,
can you
see any problems with the approach below?
mean_control mean_treatment logFC pval
padj
Gene5727 51.224797 45.371919 -0.1750427 3.474361e-08
0.0003224554
Gene3059 8.998311 5.740828 -0.6483954 1.056473e-07
0.0003268376
Gene11899 35.044302 39.027842 0.1553238 7.398559e-08
0.0003268376
Gene11724 2.556712 3.684178 0.5270535 1.959058e-07
0.0003636404
Gene12218 30.852989 23.702209 -0.3803888 1.908726e-07
0.0003636404
Gene4952 26.122068 30.466346 0.2219474 3.346424e-07
0.0005176360
My code is below. I've attached a file, dge.Rdata, that contains the
counts info that is output from readDGE, so you can have the initial
counts info.
require(edgeR)
require(sva)
source('code/annotate_edgeR.R')
files = data.frame(files=c('counts.control0', 'counts.control1',
'counts.control2', 'counts.control3', 'counts.treatment0',
'counts.treatment1', 'counts.treatment2', 'counts.treatment3'),
group=c('control', 'control', 'control', 'control',
'treatment', 'treatment', 'treatment', 'treatment'),
day=rep(0:3,2)
)
labels <- paste0(files$group, files$day)
dge <- readDGE(files=files, path='data/HTSeq/', labels=labels)
rownames(dge$counts) <- paste0('Gene', 1:nrow(dge$counts)) #Change
gene
names to anonymize data
################################
# save(dge, file='objs/dge.Rdata')
# SEE ATTACHED FILE #
###############################
## filter out the no_feature etc. rows
dge <- dge[1:(nrow(dge)-5), ]
## This mitochondrial rRNA gene takes up a massive portion of my
libraries
dge <- dge[!rownames(dge)%in%'Gene13515', ]
## filter out lowly expressed genes
keep <- rowSums(cpm(dge) > 1) >= 3 ## gene has at least 3 columns
where cpm
is > 1
dge <- dge[keep, ]
## Recompute library sizes
dge$samples$lib.size <- colSums(dge$counts)
## Normalize for lib size
dge <- calcNormFactors(dge)
## ComBat
mod <- model.matrix(~as.factor(group), data=dge$sample)
mod0 <- model.matrix(~1, data=dge$sample)
batch <- dge$sample$day
combat <- ComBat(dat=cpm(dge), batch=batch, mod=mod)
pval_combat = f.pvalue(combat, mod, mod0)
padj_combat = p.adjust(pval_combat, method="BH")
mean_control <- rowMeans(combat[, 1:4])
mean_treatment <- rowMeans(combat[, 5:8])
logFC <- log2(mean_treatment/mean_control)
res <- data.frame(mean_control, mean_treatment, logFC,
pval=pval_combat,
padj=padj_combat)
res <- res[order(res$padj), ]
R version 3.0.1 (2013-05-16)
Platform: x86_64-pc-linux-gnu (64-bit)
locale:
[1] LC_CTYPE=en_US.UTF-8 LC_NUMERIC=C
LC_TIME=en_US.UTF-8
[4] LC_COLLATE=en_US.UTF-8 LC_MONETARY=en_US.UTF-8
LC_MESSAGES=en_US.UTF-8
[7] LC_PAPER=C LC_NAME=C
LC_ADDRESS=C
[10] LC_TELEPHONE=C LC_MEASUREMENT=en_US.UTF-8
LC_IDENTIFICATION=C
attached base packages:
[1] stats graphics grDevices utils datasets methods base
other attached packages:
[1] biomaRt_2.16.0 sva_3.6.0 mgcv_1.7-23 corpcor_1.6.6
edgeR_3.2.3 limma_3.16.4
loaded via a namespace (and not attached):
[1] grid_3.0.1 lattice_0.20-15 Matrix_1.0-12 nlme_3.1-109
RCurl_1.95-4.1 tools_3.0.1
[7] XML_3.96-1.1